JP4795565B2 - MR data collection method and MRI apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an MR (Magnetic Resonance) data collection method and an MRI (Magnetic Resonance Imaging) apparatus. More specifically, even when frequency fluctuation (also referred to as frequency drift) occurs, MR data is continuously collected in an SSFP state. The present invention relates to an MR data collection method and an MRI apparatus capable of suitably performing the above.
[0002]
[Prior art]
If there is movement of a metal lump (moving metal) or temperature change in the vicinity of the MRI apparatus during the acquisition of MR data, the magnetic field magnitude and uniformity change due to the influence of the movement. Some may become inappropriate.
Therefore, navigation data for detecting frequency fluctuations is collected, and MR data when frequency fluctuations are detected is collected again, or MR data when frequency fluctuations are detected is phase-corrected. Yes.
[0003]
On the other hand, various pulse sequences are known in which MR data is continuously collected in an SSFP (Steady State Free Precession) state. For example, FIESTA (Fast Imaging Employing STeady state Acqisition), True SSFP, etc. It is also disclosed in Japanese Patent No. 2898329.
[0004]
Conventionally, there is no known MR data collection method that uses navigation data and continuously collects MR data in the SSFP state.
[0005]
[Problems to be solved by the invention]
In the conventional MR data collection method for continuously collecting MR data in the SSFP state, if there is a frequency variation during the acquisition of MR data, a part of the collected MR data includes inappropriate MR data. There was a point.
[0006]
On the other hand, it is conceivable that MR data is continuously collected in the SSFP state, navigation data is also collected, and MR data when frequency fluctuation is detected is collected again.
However, if there is a frequency fluctuation in a part of the MR data continuously collected in the SSFP state, the SSFP state will be broken by that, so the MR data after the frequency fluctuation has been corrected is not valid. It will be appropriate. Therefore, even if MR data at the time of detecting the frequency fluctuation is collected again, inappropriate MR data remains.
[0007]
Therefore, an object of the present invention is to provide an MR data acquisition method and an MRI apparatus that can suitably perform continuous acquisition of MR data in the SSFP state even when frequency fluctuations occur.
[0008]
[Means for Solving the Problems]
In the first aspect, the present invention divides the k-space into first to Mth (≧ 2) regions and continuously collects MR data of a plurality of views included in the mth region in the SSFP state. Is a MR data collection method that sequentially repeats m = 1 to m = M, collecting navigation data for detecting frequency fluctuations following the collection of MR data in a certain region, and using the navigation data to obtain frequency fluctuations. If it is not detected and the next MR data uncollected area remains, the process proceeds to the collection of MR data in the next MR data uncollected area. When frequency fluctuation is detected in the navigation data, the latest MR data collected area MR data is not collected and the MR data is re-collected at an appropriate timing thereafter, and no frequency fluctuation is detected in the navigation data. If there are no remaining R data uncollected region provides an MR data acquisition method characterized in that to terminate the acquisition of MR data.
In the MR data collection method according to the first aspect, the k-space is divided into two or more regions, and MR data of a plurality of views belonging to one region is continuously collected in the SSFP state. repeat. After MR data of a plurality of views belonging to one region are continuously collected in the SSFP state, navigation data is collected, and when frequency fluctuation is detected in the navigation data, all MR data in the region is recollected. That is, the MR data of the entire region is not collected again, but only the MR data when the frequency variation is detected is collected again. Therefore, inappropriate MR data after the SSFP state is broken does not remain, and appropriate MR data can be reliably collected.
[0009]
In a second aspect, the present invention provides an MR data collection method configured as described above, wherein when a variation in frequency is detected in the navigation data, a region where MR data has been collected most recently is set as a subsequent MR data non-collection region. The MR data collection method is characterized in that the order of the MR data non-collection regions is lowered.
In the MR data collection method according to the second aspect, the MR data in the region where the frequency fluctuation is detected is immediately collected again, so the order of filling the k space with the MR data is as originally planned.
[0010]
In a third aspect, the present invention provides an MR data collection method configured as described above, wherein when a variation in frequency is detected in the navigation data, the most recently collected MR data area is arranged in the order after the last MR data uncollected area. A method for collecting MR data is provided.
In the MR data collection method according to the third aspect, since the MR data of the next region is collected after the re-collection of the MR data of the region where the frequency fluctuation is detected, the MR data of the region where the navigation data is normal The timing when data fills the k-space is as originally planned.
[0011]
In a fourth aspect, the present invention provides the MR data collection method according to the MR data collection method configured as described above, wherein when a frequency variation is detected in the navigation data, an adjustment process is executed before the next data collection. Provide a method.
In the MR data collection method according to the fourth aspect, since the adjustment process is immediately performed when the frequency fluctuation is detected, the frequency fluctuation can be positively dealt with.
[0012]
In a fifth aspect, the present invention provides the MR data collection method having the above-described configuration, wherein the adjustment processing includes processing for adjusting a current amount of a static magnetic field coil, processing for adjusting a transmission frequency, processing for adjusting a reception frequency, and transmission. There is provided an MR data collection method characterized in that any one or a combination of two or more of a process for adjusting a phase and a process for adjusting a reception phase is provided.
In the MR data collection method according to the fifth aspect, the MRI apparatus side can be adjusted according to the frequency fluctuation.
[0013]
In a sixth aspect, the present invention is the MR data collection method having the above-described configuration, wherein the pulse sequence is a sequence in which a time integration value of a gradient magnetic field in 1TR is 0 and an FID signal and an echo signal are collected simultaneously. An MR data collection method is provided.
In the MR data collection method according to the sixth aspect, a pulse sequence called FIESTA can be used.
[0014]
In a seventh aspect, the present invention continuously collects MR data of a plurality of views in an SSFP state, collects navigation data for detecting frequency fluctuations between views, and uses the navigation data to detect frequency fluctuations. Provided is an MR data collecting method characterized by stopping MR data collection upon detection, repeating collection of navigation data, and restarting collection of MR data in the SSFP state after no frequency fluctuation is detected in the navigation data. .
In the MR data collection method according to the seventh aspect, MR data is collected by collecting navigation data while continuously collecting MR data of a plurality of views in the SSFP state, and detecting frequency fluctuations in the navigation data. stop. When the navigation data is repeatedly collected and no frequency fluctuation is detected, the MR data is continuously collected in the SSFP state. As a result, appropriate MR data can be reliably collected.
[0015]
In an eighth aspect, the present invention provides a transmission coil for transmitting an RF pulse, a gradient coil for applying a gradient magnetic field, a reception coil for receiving an NMR signal, the transmission coil and the gradient coil, Driving the receiving coil, dividing the k-space into the first to Mth (≧ 2) regions, and continuously collecting MR data of a plurality of views included in the mth region in the SSFP state; MR data collection means that repeats m = 1 to m = M in order, navigation data collection means for collecting navigation data for detecting frequency fluctuations following the collection of MR data in a certain region, and frequency fluctuations in the navigation data Determining means for determining whether or not a frequency change is detected, and if the next MR data uncollected area remains, M of the next MR data uncollected area remains. Proceeding to data collection, if a frequency variation is detected, the region where MR data has been collected most recently is regarded as a region where MR data has not been collected, and MR data is recollected at a later appropriate timing, without detecting frequency variation and There is provided an MRI apparatus characterized by comprising a data collection control means for terminating the collection of MR data if there is no remaining MR data uncollected area in the next order.
In the MRI apparatus according to the eighth aspect, the MR data collecting method according to the first aspect can be suitably implemented.
[0016]
In a ninth aspect, the present invention provides the MRI apparatus configured as described above, wherein when the data collection control unit detects a frequency variation, the area in which MR data has been collected most recently is set as the next MR data uncollected area, An MRI apparatus characterized by lowering the order of original MR data uncollected areas is provided.
In the MRI apparatus according to the ninth aspect, the MR data collecting method according to the second aspect can be suitably implemented.
[0017]
According to a tenth aspect, in the MRI apparatus having the above-described configuration, when the data collection control unit detects a frequency variation, the data collection control unit sets a region where MR data has been collected most recently after the last MR data non-collection region. An MRI apparatus characterized by being added in order is provided.
In the MRI apparatus according to the tenth aspect, the MR data collecting method according to the third aspect can be suitably implemented.
[0018]
In an eleventh aspect, the present invention provides an MRI apparatus comprising an adjustment executing means for executing an adjustment process before the next data collection when a frequency variation is detected in the MRI apparatus having the above-described configuration. provide.
In the MRI apparatus according to the eleventh aspect, the MR data collecting method according to the fourth aspect can be suitably implemented.
[0019]
In a twelfth aspect, the present invention provides the MRI apparatus having the above configuration, wherein the adjustment processing means adjusts the current amount of the static magnetic field coil, adjusts the transmission frequency, adjusts the reception frequency, and transmits the transmission phase. An MRI apparatus is provided that executes any one of a process for adjusting the received signal and a process for adjusting the reception phase, or a combination of two or more.
In the MRI apparatus according to the twelfth aspect, the MR data collecting method according to the fifth aspect can be suitably implemented.
[0020]
In a thirteenth aspect, the present invention is the MRI apparatus configured as described above, wherein the pulse sequence is a sequence in which a time integration value of a gradient magnetic field in 1TR is 0 and an FID signal and an echo signal are collected simultaneously. An MRI apparatus is provided.
In the MRI apparatus according to the thirteenth aspect, the MR data collecting method according to the sixth aspect can be suitably implemented.
[0021]
In a fourteenth aspect, the present invention provides a transmission coil for transmitting an RF pulse, a gradient coil for applying a gradient magnetic field, a reception coil for receiving an NMR signal, the transmission coil and the gradient coil, MR data collecting means for driving the receiving coil and continuously collecting MR data of a plurality of views in the SSFP state; navigation data collecting means for collecting navigation data for detecting frequency fluctuations between views; The determination means for determining whether or not frequency fluctuation is detected in the navigation data, and when the frequency fluctuation is detected, the MR data collection is stopped and the navigation data collection is repeated. After the frequency fluctuation is not detected, the SSFP state is stopped. An MRI apparatus comprising a data collection control means for resuming MR data collection is provided. To.
In the MRI apparatus according to the fourteenth aspect, the MR data collecting method according to the seventh aspect can be suitably implemented.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in more detail with reference to embodiments shown in the drawings. Note that the present invention is not limited thereby.
[0023]
-First embodiment-
FIG. 1 is a block diagram showing an MRI apparatus according to the first embodiment of the present invention.
In the MRI apparatus 100, the magnet assembly 1 has a space portion (bore) for inserting the subject therein, and a static magnetic field that applies a constant static magnetic field to the subject so as to surround the space portion. Gradient for generating the coil 1p and gradient magnetic fields of the X, Y, and Z axes (a slice gradient axis, a lead gradient axis, and a phase encode gradient axis are formed by a combination of the X, Y, and Z axes) A magnetic field coil 1g, a transmission coil 1t that applies an RF pulse for exciting spins of nuclei in the subject, and a reception coil 1r that detects an NMR signal from the subject are arranged. The static magnetic field coil 1p, gradient magnetic field coil 1g, transmission coil 1t and reception coil 1r are connected to a static magnetic field power source 2, a gradient magnetic field drive circuit 3, an RF power amplifier 4 and a preamplifier 5, respectively.
[0024]
The sequence storage circuit 6 operates the gradient magnetic field driving circuit 3 based on the stored pulse sequence in accordance with a command from the computer 7 to generate a gradient magnetic field from the gradient magnetic field coil 1g of the magnet assembly 1 and gate modulation. The circuit 8 is operated, and the carrier wave output signal of the RF oscillation circuit 9 is modulated into a pulse signal having a predetermined timing and a predetermined envelope shape, which is added as an RF pulse to the RF power amplifier 4 and power amplified by the RF power amplifier 4 Thereafter, it is applied to the transmission coil 1t of the magnet assembly 1 to selectively excite a desired imaging surface.
[0025]
The preamplifier 5 amplifies the NMR signal from the subject received by the receiving coil 1 r of the magnet assembly 1 and inputs it to the phase detector 10. The phase detector 10 uses the carrier wave output signal of the RF oscillation circuit 9 as a reference signal, phase-detects the NMR signal from the preamplifier 5, and provides it to the AD converter 11. The AD converter 11 converts the analog signal after phase detection into digital data and inputs it to the computer 7.
[0026]
The computer 7 is responsible for overall control such as receiving information input from the operation console 12. Further, the computer 7 reads digital data from the AD converter 11 and performs an image reconstruction calculation to generate an MR image.
The display device 13 displays the MR image.
[0027]
FIG. 2 is a conceptual diagram of k-space and MR data collection trajectory.
The k space is a two-dimensional space in the lead axis direction and the phase encode axis direction.
Here, it is assumed that there are views # 1 to # 16 in the phase encode axis direction.
The k space includes the first area of views # 1 to # 4, the second area of views # 5 to # 8, the third area of views # 9 to # 12, and the first areas of views # 13 to # 16. It is assumed that it is divided into four areas.
Note that the view number and the area number can be assigned freely.
[0028]
FIG. 3 is an example of a pulse sequence called FIESTA.
In this FIESTA sequence, an RF pulse is repeatedly hit with a TR shorter than T2 to be measured, and MR data is collected from an FID signal and an echo signal (spin echo signal or stimulated echo signal) that appear in an SSFP state. A gradient magnetic field waveform is employed such that the time integral value of the gradient magnetic field in 1TR is “0”. Further, the phase encode axis gradient is sequentially changed to a size corresponding to each view.
[0029]
FIG. 4 is an example of a pulse sequence for collecting navigation data.
In this navigation sequence, a gradient magnetic field other than the slice axis is omitted from the FIESTA sequence.
[0030]
FIG. 5 is an exemplary diagram of a data collection order according to the first embodiment.
First, the FIESTA sequence is repeated without collecting MR data to enter the SSFP state. This is called empty.
When the SSFP state is reached, MR data of views # 1 to # 4 in the first area are continuously collected by the FIESTA sequence.
Next, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal (no static magnetic field fluctuation) or abnormal (has a static magnetic field fluctuation), and the navigation data is normal and the next MR data. If an uncollected area remains, the process proceeds to MR data collection in the next MR data uncollected area. Here, the process proceeds to MR data collection in the second region.
[0031]
In the MR data collection of the second region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 5 to # 8 in the second area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the third region.
[0032]
In MR data collection in the third region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 9 to # 12 in the third area are continuously collected by the FIESTA sequence.
Subsequently, the navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is abnormal, the area where the latest MR data is collected is regarded as the next MR data uncollected area, Proceed to MR data collection in the next MR data uncollected area. Here, the process proceeds to MR data collection in the third region again.
[0033]
In the MR data collection of the third region again, first, abnormality adjustment processing is executed according to the navigation data. For example, the current amount of the static magnetic field coil 1p is adjusted, the transmission frequency is adjusted, the transmission frequency and the reception frequency are adjusted, and the transmission phase and the reception phase are adjusted.
Next, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 9 to # 12 in the third area are continuously recollected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the fourth region.
[0034]
In the MR data collection of the fourth region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 13 to # 16 in the fourth area are continuously collected by the FIESTA sequence.
Subsequently, the navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is abnormal, the area where the latest MR data is collected is regarded as the next MR data uncollected area, Proceed to MR data collection in the next MR data uncollected area. Here, the process proceeds to MR data collection in the fourth region again.
[0035]
In the MR data collection of the fourth region again, first, abnormality adjustment processing is executed according to the navigation data.
Next, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 13 to # 16 in the fourth area are continuously collected again by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and there is no remaining MR data uncollected area in the next order, the data collection is terminated.
[0036]
According to the first embodiment described above, the SSFP state has been broken because the MR data of one entire region is not collected again, but only the MR data when the frequency variation is detected is collected again. The subsequent inappropriate MR data will not be left, and appropriate MR data can be reliably collected. In addition, the k space can be filled with MR data in the order as originally planned (in the order of # 1, # 2, # 3,..., # 16).
[0037]
-Second Embodiment-
The block diagram of the MRI apparatus according to the second embodiment of the present invention is the same as FIG.
[0038]
FIG. 6 is an exemplary diagram of a data collection order according to the second embodiment.
First, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 1 to # 4 in the first area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the second region.
[0039]
In the MR data collection of the second region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 5 to # 8 in the second area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the third region.
[0040]
In MR data collection in the third region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 9 to # 12 in the third area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is abnormal, the latest MR data collection area is arranged in the order after the last MR data non-collection area. In addition, the process proceeds to MR data collection in the next MR data uncollected area. Here, the third region is added after the fourth region, and the process proceeds to MR data collection for the fourth region.
[0041]
In MR data collection in the fourth region, first, abnormality adjustment processing is executed according to the navigation data.
Next, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 13 to # 16 in the fourth area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the third region.
[0042]
In the MR data collection of the third region again, first, the SSFP state is set due to the air.
When the SSFP state is reached, MR data of the views # 9 to # 12 in the third area are continuously recollected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is abnormal, the latest MR data collection area is arranged in the order after the last MR data non-collection area. In addition, the process proceeds to MR data collection in the next MR data uncollected area. Here, since there is no remaining MR data uncollected area in the next order, the third area is set as the next order, and the process proceeds to MR data collection in the third area.
[0043]
In the MR data collection of the third region again and again, first, abnormality adjustment processing is executed according to the navigation data.
Next, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 9 to # 12 in the third area are continuously collected again by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence to determine whether the navigation data is normal or abnormal. If the navigation data is normal and there is no remaining MR data uncollected area in the next order, the MR data collection is terminated.
[0044]
According to the second embodiment described above, the SSFP state has been broken because the MR data of one entire region is not collected, but only the MR data when the frequency variation is detected is collected again. The subsequent inappropriate MR data will not be left, and appropriate MR data can be reliably collected. In addition, the timing at which the MR data in the region where the navigation data is normal (the first region, the second region, and the third region in the example of FIG. 6) fills the k space is as originally planned.
[0045]
-Third embodiment-
The block diagram of the MRI apparatus according to the third embodiment of the present invention is the same as FIG.
[0046]
FIG. 7 is an exemplary diagram of a data collection order according to the third embodiment.
First, the SSFP state is set in the air.
When the SSFP state is reached, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal, the process proceeds to MR data collection in the next MR data uncollected area. Here, the process proceeds to MR data collection for the first region.
[0047]
In the MR data collection of the first region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 1 to # 4 in the first area are continuously collected by the FIESTA sequence.
Subsequently, the navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal, the process proceeds to the collection of MR data in the next MR data non-collection area. Here, the process proceeds to MR data collection in the second region.
[0048]
In the MR data collection of the second region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 5 to # 8 in the second area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal. If the navigation data is normal and the next MR data uncollected area remains, the next MR data is not collected. Proceed to collecting MR data for the region. Here, the process proceeds to MR data collection in the third region.
[0049]
In MR data collection in the third region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of views # 9 to # 12 in the third area are continuously collected by the FIESTA sequence.
Subsequently, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal.
[0050]
If the navigation data is abnormal, an abnormality adjustment process is executed according to the navigation data.
Next, the SSFP state is set in the air.
When the SSFP state is reached, navigation data is collected by the navigation sequence, and it is determined whether the navigation data is normal or abnormal.
This is repeated until the navigation data becomes normal.
[0051]
When the navigation data becomes normal, the process proceeds to MR data collection in the next MR data uncollected area. Here, the process proceeds to MR data collection in the fourth region.
[0052]
In the MR data collection of the fourth region, first, the SSFP state is set in the air.
When the SSFP state is reached, MR data of the views # 13 to # 16 in the fourth area are continuously collected by the FIESTA sequence.
If there is no remaining MR data uncollected area in the next order, the MR data collection ends.
[0053]
According to the third embodiment, since the MR data collection is stopped when the frequency fluctuation is detected and the MR data collection is resumed in the SSFP state when the frequency fluctuation is not detected, the appropriate MR data is obtained. Can be collected reliably.
[0054]
【The invention's effect】
According to the MR data collection method and MRI apparatus of the present invention, continuous collection of MR data in the SSFP state can be suitably performed even when frequency fluctuations caused by moving metal or the like occur.
[Brief description of the drawings]
FIG. 1 is a block diagram of an MRI apparatus according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram of a k-space and a view.
FIG. 3 is a pulse sequence diagram of an example of a FIESTA sequence.
FIG. 4 is a pulse sequence diagram of an example of a navigation sequence.
FIG. 5 is an exemplary diagram of a data collection order according to the first embodiment.
FIG. 6 is an exemplary diagram of a data collection order according to the second embodiment.
FIG. 7 is a view showing an example of a data collection order according to the third embodiment.
[Explanation of symbols]
100 MRI system
1 Magnet assembly
1g gradient magnetic field coil
1p static magnetic field coil
1r Receiver coil
1t Transmitting coil
6 Sequence memory circuit
7 Calculator

Claims (14)

From m = 1 to m = M, the k-space is divided into 1st to Mth (≧ 2) regions, and MR data of a plurality of views included in the mth region is continuously collected in the SSFP state. An MR data collection method that repeats in order, collecting navigation data for detecting static magnetic field fluctuations following the collection of MR data in a certain region, and detecting the static magnetic field fluctuations in the navigation data and performing the next MR If the data uncollected area remains, the process proceeds to the MR data collection of the next MR data uncollected area. When the static magnetic field fluctuation is detected by the navigation data, the area where the latest MR data is collected is referred to as the MR data uncollected area. As a result, MR data is re-collected at an appropriate timing thereafter, and no static magnetic field fluctuation is detected in the navigation data, and the next MR data uncollected region remains. MR data acquisition method characterized in that to terminate the acquisition of MR data if there are no. 2. The MR data collection method according to claim 1, wherein when a static magnetic field variation is detected in the navigation data, a region where MR data has been collected most recently is set as the next MR data uncollected region, and the original MR data uncollected region. MR data collection method characterized by lowering the order. 2. The MR data collection method according to claim 1, wherein when a static magnetic field variation is detected in the navigation data, the most recently collected region of MR data is added in order after the last MR data uncollected region. MR data collection method. 4. The MR data collection method according to claim 1, wherein, when a static magnetic field variation is detected in the navigation data, an adjustment process is executed before the next data collection. 5. Collection method. 5. The MR data collection method according to claim 4, wherein the adjustment processing includes processing for adjusting a current amount of a static magnetic field coil, processing for adjusting a transmission frequency, processing for adjusting a reception frequency, processing for adjusting a transmission phase, and reception. An MR data collection method characterized in that any one or a combination of two or more of the processes for adjusting the phase. 6. The MR data acquisition method according to claim 1, wherein the pulse sequence is a sequence in which a time integration value of a gradient magnetic field in 1TR is 0 and an FID signal and an echo signal are acquired simultaneously. MR data collection method characterized by the above. MR data of a plurality of views is continuously collected in the SSFP state, and navigation data for detecting static magnetic field fluctuations between views is collected. When static magnetic field fluctuations are detected in the navigation data, the MR data collection is stopped. MR data collection method, characterized in that collection of navigation data is repeated, and MR data collection in the SSFP state is resumed after no static magnetic field fluctuation is detected in the navigation data. Driving a transmission coil for transmitting RF pulses, a gradient coil for applying a gradient magnetic field, a reception coil for receiving NMR signals, the transmission coil, the gradient coil, and the reception coil, k-space Is divided into first to Mth (≧ 2) regions, and MR data of a plurality of views included in the mth region are continuously collected in the SSFP state in order from m = 1 to m = M. MR data collection means, navigation data collection means for collecting navigation data for detecting static magnetic field fluctuations following the collection of MR data in a certain region, and whether or not static magnetic field fluctuations are detected in the navigation data If no change in the static magnetic field is detected and there is a remaining MR data uncollected area, the process proceeds to MR data collection in the next MR data uncollected area. When a change is detected, the region where the latest MR data has been collected is regarded as a region where MR data has not been collected, and MR data is re-collected at a later appropriate timing. An MRI apparatus comprising data collection control means for terminating the collection of MR data if no collection area remains. 9. The MRI apparatus according to claim 8, wherein when the static magnetic field fluctuation is detected, the data collection control means sets the area where MR data was collected most recently as the next MR data non-collection area, and does not collect the original MR data. An MRI apparatus characterized by lowering the order of regions. 9. The MRI apparatus according to claim 8, wherein the data collection control means adds the area where MR data was most recently collected in order after the last MR data uncollected area when a static magnetic field variation is detected. MRI equipment. 11. The MRI apparatus according to claim 8, further comprising adjustment processing means for executing adjustment processing before the next data collection when a static magnetic field variation is detected. . 12. The MRI apparatus according to claim 11, wherein the adjustment processing means includes a process for adjusting a current amount of a static magnetic field coil, a process for adjusting a transmission frequency, a process for adjusting a reception frequency, a process for adjusting a transmission phase, and a reception phase. An MRI apparatus that executes any one or a combination of two or more of the processes for adjusting the frequency. The MRI apparatus according to any one of claims 8 to 12, wherein the pulse sequence is a sequence in which a time integration value of a gradient magnetic field in 1TR is 0 and an FID signal and an echo signal are collected simultaneously. MRI equipment. A transmission coil for transmitting an RF pulse, a gradient coil for applying a gradient magnetic field, a reception coil for receiving an NMR signal, and the transmission coil, the gradient coil, and the reception coil, MR data collecting means for continuously collecting MR data of views in the SSFP state, navigation data collecting means for collecting navigation data for detecting static magnetic field fluctuations between views, and detecting static magnetic field fluctuations using the navigation data The determination means for determining whether or not the static magnetic field variation is detected, the MR data collection is stopped and the navigation data collection is repeated, and the MR data collection in the SSFP state is resumed after the static magnetic field variation is not detected. An MRI apparatus comprising: a data collection control means for performing

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